DE1263164B - Control procedure for changing the frequency and voltage of an inverter operating in switching mode - Google Patents

Description

Control method for changing the frequency and voltage of a in switching operation inverter It is known from direct current with Using inverters to generate alternating voltages. One can also by using for example three individual inverters from the same DC source be fed, build a normal three-phase system with 120 ° phase shift. The inverters used only work as switches and set the direct voltage to a square wave alternating voltage. Becomes a sinusoidal Output voltage is required, sieve media must also be used.

This known arrangement has certain disadvantages: The inverter works with the frequency required for the load. Is it here? around. a relatively low frequency (e.g. 50 Hz), then those are necessary to achieve a sinusoidal voltage required screen means extremely large. Should the Frequency are changed, then appropriate interventions in the control of the Switching elements contained in the inverter are required. When changing the However, the frequency of this known inverter remains the amplitude of the square-wave voltage unchanged, since the switches only continuously control the voltage of the direct current source reverse polarity. This creates difficulties when the consumer is out of an iron inductance exists (e.g. AC motor, vibration drive, magnetic amplifier). Such consumers are known for economic and space-saving reasons so designed that the induction in iron is limited by saturation and iron losses Has maximum value. This induction only remains constant as long as the ratio of The size of the feeding voltage to the frequency of the feeding voltage remains constant. For example, an AC motor via an inverter is becoming more popular Kind of fed, this motor is no longer when the feed frequency is increased fully utilized as the voltage of this inverter remains constant.

It is still a control method for changing the frequency and the voltage of an inverter operating in switching mode became known, in which the mean value of the output voltage is determined by periodic pulse width modulation of the inverter, which operates at a constant and relatively high frequency, is sinusoidal fluctuates and the resulting lower wave over sieve means that leads to restraint the high-frequency voltages are used, the consumer is supplied, these Sub-wave in its frequency by changing the period of the pulse width modulation and in their amplitude by changing the intensity of the periodic pulse width fluctuation is adjustable.

In this known method, half-sine waves are therefore initially used formed, which to give a sinusoidal alternating voltage, but disadvantageous require a special periodic polarity reversal in the cycle of the low-frequency voltage.

The invention relates to a control method for changing the frequency and the voltage of an inverter operating in switching mode, in which on every positive impulse is followed by a negative impulse.

According to the invention, the duration fluctuates as the ratio changes of the positive and negative pulse within one period is the mean value the output voltage of the inverter operating at a constant and relatively high frequency sinusoidal; and the resulting sub-wave is passed over sieve means that are used for Serve restraint of the high frequency voltage, supplied to the consumer, whereby this sub-wave in its frequency by changing the period of the pulse widths = modulation and in its amplitude by changing the intensity of the periodic Pulse width fluctuation is adjustable.

The advantage of the subject matter of the invention over the one described above known arrangement is that the periodically necessary polarity reversal switching action avoided due to a corresponding control of the high frequency alternating voltage is. On the basis of FIG. 1 to 3 are intended to explain the invention in more detail will. In Fig. 1 is with 1 a known per se, working in switching mode Inverter called. It is fed by the DC voltage source 2. His Output voltage U "is via filter means, which in the exemplary embodiment consists of a Series inductance 4 and a transverse capacitance 5 exist, fed to a consumer 3. This consumer 3 is shown in the exemplary embodiment as an inductive consumer and can e.g. B. be a stator winding of an asynchronous motor. The inverter 1 works with a frequency that is considerably higher than that for the to be fed Consumer 3 required frequency. As long as the switching control of the in the inverter 1 is not influenced, the output voltage U " the in F i g. 2 a shown square wave voltage. t means the time axis. The area between the positive and negative half-wave blocks is constant. Because the frequency this square-wave voltage U "is very high, the entire voltage drops at the upstream Inductance 4 from, while the inductive load 3 through the capacitor 5 opposite the high frequency is practically short-circuited. To the inductive consumer 3 is no voltage.

Periodic pulse width modulation now changes the mean value of the output voltage U "sinusoidally. The positive and negative half-wave blocks of the output voltage U" are no longer the same size, but change according to a sinusoidal function. The high-frequency voltage U "is therefore subject to a low-frequency voltage Uä (FIG. 2b). The inductance 4 does not represent an obstacle to this low-frequency voltage, while the capacitor 5 is to be regarded as not present because of its high reactance. The low-frequency voltage is therefore on consumer 3. If the period with which the pulse width modulation fluctuates is changed, the frequency of the voltage on consumer 3 also changes.

The size of the low-frequency output voltage can be changed by the intensity of the periodic pulse width fluctuation, ie the ratio of t1 to t2 (FIG. 2 b) changes to a greater or lesser extent. The amplitude of the sub-wave voltage Uä can therefore be changed, although the amplitude of the output voltage U, of the switching inverter remains unchanged. If one wants to achieve, for example, that an iron inductance to be fed is always operated with the same induction despite a change in the frequency of the feeding voltage, one only needs to ensure that the intensity of the periodic pulse width fluctuation and the period of the pulse width modulation are changed at the same time so that the quotient of the amplitude and frequency of the sub-wave remains approximately constant. Ultimately, of course, only the ratio of t: t2 can be set in the inverter itself; because both the frequency and the amplitude of the sub-wave are determined by the ratio t,.: t2. The process can be imagined in such a way that the ratio ti : t2 is controlled by a sinusoidal alternating voltage. If the instantaneous value of this alternating voltage is zero, the ratio t1 : t2 has the value one. By specifying the frequency of this alternating voltage via the input 1. f, the frequency of the sub-wave is changed and by specifying the amplitude of this alternating voltage via the input 1a, the amplitude of the sub-wave voltage is changed.

If you want an inductive consumer, z. B. an AC motor operate in such a way that, regardless of the frequency, the iron is always exploited is at the limit drawn by the saturation, then one can do this according to a Further development of the invention, the intensity of the periodic pulse width fluctuations depending on the motor current drawn so that this current is its Sinus shape does not lose, but otherwise assumes the largest possible value.

It is well known that the motor current deviates from the sinusoidal shape only if the iron is too saturated. But that means that the Induction exceeds acceptable levels. So it must be the deviation of the consumer current can be determined from the sinusoidal shape and the variable describing this deviation in the sense of a control on the fully open input 1 a des. Inverter are given over which the intensity of the periodic pulse width fluctuations is adjustable. In Fig. 1, this part of the arrangement is shown in dashed lines. In point 6, the consumer current is detected and in element 7 the deviation of the Consumer current is formed by the variable describing the sinusoidal shape: This is based on given the entrance 1a.

Claims (3)

Claims: 1. Control method for changing the frequency and the voltage of an inverter operating in switching mode, in which each positive impulse followed by a negative impulse, characterized in that by change the ratio of the duration of the positive and negative impulse within one Period of the mean value of the output voltage of the constant and relatively high Frequency working inverter (1) fluctuates snus-shaped and the resulting Lower wave over sieve means (4, 5), which are used to hold back the higher frequency voltage serve, is fed to the consumer, this sub-wave in its frequency by changing the period of the pulse width modulation and in its amplitude adjustable by changing the intensity of the periodic pulse width fluctuation is. 2. Control method according to claim 1, in particular for feeding one from one Iron inductance (e.g. AC motor) existing consumer, characterized in that that by simultaneously changing the intensity of the periodic pulse width fluctuation and the period of the pulse width modulation is the quotient of amplitude and frequency the lower wave (consumer voltage) is kept approximately constant. 3. Tax Procedure according to claim 1 to achieve an utilization which is always at the saturation limit of the iron of an inductive consumer (e.g. alternating current machine), thereby marked, that the deviation of the consumer current from the sinusoidal shape is determined (7) and this deviation in the sense of steering towards the fully opened entrance (1 a) of the inverter is given over which the intensity of the periodic Pulse width fluctuation is adjustable. Publications considered: German Interpretation document No. 1065 080.